14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILES: HISTORY • Early 1950’s in Italy – Conceived to underpin historic structures and monuments damaged in WW II. • 1952 - Palo Radice (Root Pile) patented by Fondedile (Dr. Fernando Lizzi). Figure 1-2. Classical Arrangement of Root Piles for Underpinning. (FHWA NHI-05-039) Revised 9/2012
From FHWA SA-97-020, Bruce (2008), and Bennett (2010)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILES: HISTORY • 1970 – Fondedile Corp. established in US. • 1972 – First use of Root Piles in US (Illinois). • 1980 to 90 – Decline and Closure of Fondedile in US. • Early 1980’s - Big “Push” by East Coast Contractors. Figure 1-3. Typical Network of Reticulated Micropiles. (FHWA NHI-05-039) Revised 9/2012
From FHWA SA-97-020, Bruce (2008), and Bennett (2010)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILES: HISTORY • 1989 – Loma Prieta & Start of Micropile Seismic Retrofits on West Coast. • 1996 to 1998 – Williamsburg Bridge Retrofit (NYC). • 1993 to 1997 – “FHWA State of the Practice” Report. Micropile Seismic Retrofit (Photograph courtesy of Palmetto Gunite) Revised 9/2012
From FHWA SA-97-020, Bruce (2008), and Bennett (2010)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILES: HISTORY • 1996 to 1999 – FHWA Implementation Manual • 1997 – International Workshop on Micropiles (IWM) Founded • 2002 – ADSC develops FHWA/NHI Course • 2005 – International Society of Micropiles (ISM) Founded Dulles Town Center Underpinning (Photograph courtesy of Dennis Triplett LLC) Revised 9/2012
From FHWA SA-97-020, Bruce (2008), and Bennett (2010)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
DEEP FOUNDATION CLASSIFICATIONS Figure 8.1. FHWA NHI-05-042 Design and Construction of Driven Pile Foundations Volume I.
Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
DEEP FOUNDATIONS: MICROPILES (A.K.A. MINI, PIN) Table 8-1. FHWA NHI-05-042 (from NAVFAC DM7.02).
FHWA NHI-05-039 Typ. < 12 inch dia. Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
FHWA DEFINITION A micropile is a small-diameter (typically less than 12 in.), drilled and grouted non-displacement pile that is typically reinforced.
Figure 1-1. Micropile Construction Sequence. (FHWA NHI-05-039) Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE APPLICATIONS • Restricted access or is located in a remote area • Required support system needs to be in close proximity to existing structures • Supplemental Existing Structure Support (e.g. Settlement) • Difficult ground conditions (e.g., karstic areas, uncontrolled fills, boulders) • Pile driving would result in soil liquefaction (dubious) • Vibration and/or noise needs to be minimized • Hazardous or contaminated spoil material will be generated during construction • Adaptation of support system to existing structure is required • Scour Revised 9/2012
After FHWA NHI-05-039
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE APPLICATIONS Figure 3-5. Micropiles for Foundation Support of Transportation Applications. (FHWA NHI-05-039)
Revised 9/2012
After FHWA NHI-05-039
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE LIMITATIONS • Buckling (Seismic and Liquefaction). • High Slenderness Ratio • Lateral Capacity • Limited experience in their use for slope stabilization • Requires good QC / QA • Cost. • Not cost effective vs. conventional piling systems in open headroom conditions • High lineal cost relative to conventional piling systems • Requires specialized equipment Revised 9/2012
After FHWA NHI-05-039 & ADSC
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
FHWA CLASSIFICATION SYSTEM Based on two (2) Criteria 1. Philosophy of Behavior (Design) 2. Method of Grouting (Construction) Figure 2-1. CASE 1 Micropiles. (FHWA NHI-05-039) Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
FHWA CLASSIFICATION SYSTEM PHILOSOPHY OF BEHAVIOR (DESIGN) CASE 1: Micropile loaded directly and micropile reinforcement resists the majority of the applied load. • Primary resistance provided by steel reinforcement and side resistance over bond zone. • >90% of ALL North America Projects are CASE 1. Revised 9/2012
Figure 2-3. CASE 1 Micropile Arrangements. (FHWA NHI-05-039)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
FHWA CLASSIFICATION SYSTEM PHILOSOPHY OF BEHAVIOR (DESIGN) CASE 2: Networks of reticulated micropiles as components of a reinforced soil mass which is used to provide stabilization and support. • Lightly reinforced. • Structural loads to entire soil mass. • Design methods “Iffy”. Revised 9/2012
Figure 2-2. CASE 2 Micropile Arrangements. (FHWA NHI-05-039)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
FHWA CLASSIFICATION SYSTEM METHOD OF GROUTING (CONSTRUCTION) Type A: Neat cement or sandcement grout placed under gravity. Type B: Neat cement grout injected into drill hole under pressure (72145 psi), while withdrawing temporary drill casing or auger. Type C: Two-Step Process.
Figure 2-5. Grouting Methods. Revised 9/2012
(FHWA NHI-05-039)
• Neat cement grout under gravity (Type A). • After 15-25 minute, Sleeved grout pie w/o packer (>145 psi).
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
FHWA CLASSIFICATION SYSTEM METHOD OF GROUTING (CONSTRUCTION) Type D: Two-Step Process • Neat cement grout placed under gravity (Type A & C) or pressurized (Type B) • Full Hardening of grout (15-25 minutes) • Pressure grouted through sleeved grout pile (260-1160 psi)
Figure 2-5. Grouting Methods. Revised 9/2012
(FHWA NHI-05-039)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
AASHTO CLASSIFICATION SYSTEM METHOD OF INSTALLATION Type E: Hollow Bar Drilling with Grout Injection. • “Injection Bore Bars” • “Self Drilling”
Figure courtesy of Geosystems LP (after FHWA and AASHTO). Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
AASHTO CLASSIFICATION SYSTEM METHOD OF INSTALLATION Type E: Hollow Bar Drilling with Grout Injection. • TITAN IBO Example
Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
TYPE E MICROPILES EXHUMED TITAN IBO MICROPILES
Figures courtesy of Con-Tech Systems Ltd. Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
FHWA CLASSIFICATION SYSTEM METHOD OF GROUTING (CONSTRUCTION) Table 2-1. Details of Micropile Classification Based on Type of Grouting (after Pearlman and Wolosick, 1992). (FHWA NHI-05-039)
Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE CASE 1 & 2
(1 & 2) (1 & 2)
APPLICATIONS: TRANSPORTATION
(CASE 2)
(1 & 2)
CASE 1
Figure 3-1. Classification of Micropile Applications.
(FHWA NHI-05-039) Revised 9/2012
Table 3-1. Relationship Between Micropile Application, Design Behavior and Construction Type (modified after FHWA, 1997).. (FHWA NHI-05-039)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE APPLICATIONS: TRANSPORTATION
Figure 3-13. Slope Stabilization at FH-7 Project in
Mendocino National Forest, California. (FHWA NHI-05-039) Figure 3-3. Protection of an Existing Diaphragm Wall with a Secant
Micropile Screen using Anti-acid Mortar (after Bachy, 1992). (FHWA NHI-05-039)
Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE CONSTRUCTION: DRILLING
Figure 4-1. Typical Micropile Construction Sequence Using Casing. Revised 9/2012
(FHWA NHI-05-039)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE CONSTRUCTION: DRILLING • • • •
Rotary only Drifter, Rotation/Percussion Double Head Systems Sonic Head
Revised 9/2012
Figures Courtesy of ADSC.
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE CONSTRUCTION OVERBURDEN DRILLING
Figure 4-9. Overburden Drilling Methods Revised 9/2012
(modified after Bruce, 1989). (FHWA NHI-05-039)
Table 4-1. Overburden Drilling Methods (after Bruce, 1989).
(FHWA NHI-05-039)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE CONSTRUCTION: GROUTING • High strength and stability (i.e., bleed), but must also be pumpable (Typical w/c ratios in the range of 0.40 to 0.50 by weight). • Grouts are produced with potable water, to reduce the danger of reinforcement corrosion. • Type I/II cement conforming to ASTM C150/AASHTO M85 is most commonly used. • Neat cement-water grout mixes are most commonly used. • Design compressive strengths of 28 to 35 MPa (4,000 to 5,000 psi) can be attained with properly produced neat cement grouts. • If admixtures and/or additives are used, it is essential that they are chemically compatible. This is best achieved by using only one chemical supplier, and not by “mixing and matching”. Revised 9/2012
Figure 4-9. Effect of Water Content on Grout Compressive Strength and Flow Properties (after Littlejohn and Bruce, 1977). (FHWA NHI-05-039)
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE CONSTRUCTION: GROUTING
Revised 9/2012
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE CONSTRUCTION: DRILLING
Revised 9/2012
Figures Courtesy of ADSC.
14.528 DRILLED DEEP FOUNDATIONS Micropile Design and Construction
MICROPILE DESIGN Table 5-1. Design Steps for Micropiles used for Structural Foundations.
(FHWA NHI-05-039)
Figure 5-1. Detail of a Composite Reinforced
Micropile. (FHWA NHI-05-039) Revised 9/2012
